The optically active urobilin model compound 7 was synthesized, in which Me groups instead of H-atoms are bound to the asymmetric centers, thus preventing loss of chirality by tautomerization. The key intermediate of the eleven-step synthesis of 7 is the 1,4,5,2 0-tetrahydro-lO-hydroxy-l-oxo-l1H-dipyrrin-9-carboxylate ruc-2, which could be resolved into enantiomers by fractional crystallization of the corresponding methyl N-[1 -(naphth-1-yl)ethyl]carbamates 3 and 4. The absolute configuration of enantiomerically pure (-)-2 was determined by X-ray diffraction analysis of its camphor-10-sulfonate 5. As the CD spectrum of the urobilin analogue 7 obtained from (-)-(R)-2 displays a positive Cotton effect, the present results prove, in connection with previous work, that substitution of Me groups for the H-atoms bound to the asymmetric centers of a chiral urobilin chromophore do not influence the relationship between absolute configuration of the latter and its helicity.Urobilinoids (urobilins and stercobilins) are the final products of heme catabolism in humans and mammalians [2]. This class of bile pigments deserve particular interest, however, since the existence of the urobilin chromophore was demonstrated in both algal [3] [4] and bacterial [S] accessory pigments of the phycoerythrin type, which are involved in the process of oxygenic photosynthesis in these organisms.Both urobilins and stercobilins are characterized by the presence of two asymmetric C-atoms (C(4) and C( 16) in the partially hydrogenated 22H-bilin-l,19(21H,24H)-dione chromophore). Thus, symmetrically substituted urobilins (4,5,15,16-tetrahydro-22H-bilin-I, 19(21H,24H)-diones) may be either chiral or sigmasymmetric depending on whether the relative configurations at both asymmetric C-atoms are the same or opposite, respectively (cf. 7). Chiral urobilins are characterized by the extremely high specific rotation of their hydrochlorides (e.g.[a]? = +5000 for natural d-wobilin IXa [6]), which was attributed to the presence of an inherently dissymmetric coiled dipyrrin chrornophore whose chirality is preserved by intramolecular H-bonding [7]. In this model, the helicity of the dipyrrin chromophore is determined by the absolute configurations of the asymmetric atoms C(4) and C(16). Recently, it could be proved that a (S,S)-configurated urobilin molecule displays a negative Cotton effect in the absorption range of the dipyrrin chromophore [8]. Until now, however, the precise structure of the optically active i, Part 16: 111.
